Formamidine pesticides: octopamine-like actions in a firefly.

The formamidine pesticide chlordimeform and its N-demethylated metabolites cause the light organ of the firefly Photinus pyralis L. to glow brightly. Monodemethyl chlordimeform is active at doses as low as 5 nanograms per insect when applied topically. This action is postsynaptic and probably involves membrane-bound receptors since cyproheptadine blocks the glows induced by both monodemethyl chlordimeform and octopamine, the putative neurotransmitter in the light organ. The pesticidal and pestistatic properties of the formamidines may result from actions on octopaminergic systems.

Chemistry, biological activity, and uses of formamidine pesticides.

The formamidines, a relatively new group of acaricide-insecticides, are novel both in their range of biological activities and in their mode of action, which is presently unknown. This paper is a review of the historical development, properties, structures, uses, and chemistry of this group of pesticides, with particular emphasis on chlordimeform (Galecron or Fundal), N'-4-chloro-o-tolyl-N,N-dimethylformamidine, and amitraz, 1,3=di-(2,4-dimethylphenylimino)-2-methyl-2-azapropane. Their biological activity and uses are defined by their toxicity to spider mites, ticks, and certain insects, and they are particularly effective against juvenile and resistant forms of these organisms. A significant, but poorly understood feature of their field effectiveness is their breadth of toxic action which includes direct lethality, excitant-repellant behavioral effects, and chemosterilization. They are generally of low hazard for nontarget species with the significant exception of predaceous mites. Several aspects of the chemistry of these compounds are considered, including structure--activity relations, synthetic pathways, isomerism and configuration, and their chemical and environmental stability. A significant feature of the metabolism and toxicity of these agents is the possible activation of chlordimeform by N-demethylation in vivo. Strong evidence for this has been presented with the cattle tick, but recent results discussed here suggest that in other species, i.e., mice, German cockroaches or black cutworm eggs, N-demethylation is neither a strong activation nor a detoxication reaction.

Increased feeding in rats treated with chlordimeform and related formamidines: a new class of appetite stimulants.

Low doses of the formamidine pesticide, chlordimeform (CDM) induce voracious daytime feeding in non-food deprived rats. Following CDM (10 mg/kg), food intakes were five times control intakes after 3 h and 1.1 times control intakes after 24 h. Other selected formamidines, such as the N-demethylated metabolite of CDM, and amitraz, increased 3-h food intake by two and five times control intake, respectively. Anorexia accompanied by excessive CNS stimulation was noted with higher doses of CDM (above 40 mg/kg) and other formamidines. This contrasts with the sedation usually observed with high doses of other structurally diverse appetite stimulants. In addition, hyperphagia was not observed with other CNS stimulants or local anesthetics such as amphetamine, cocaine, and holocaine. Thus the formamidines constitute a new class of appetite stimulants, which should prove to be useful agents for the study of feeding behavior.

XAMI and DCDM, agonists at cAMP-associated octopamine receptors in cockroach nerve cord, produce centrally mediated antinociception in mice.

The ability of XAMI (2,3-xylylaminomethyl-2'-imidazoline), the most potent agonist of cAMP-associated octopamine-sensitive adenylate cyclase in cockroach (Periplaneta americana) nerve cord yet reported, and DCDM (N-demethylchlordimeform), a partial octopamine agonist in this preparation, to produce centrally mediated antinociception in mice was evaluated. The antinociception produced by these compounds was compared to that previously reported for p-octopamine, a phenylethylamine and endogenous mammalian hydroxyphenolic analog of norepinephrine. Consonant with the reported greater agonistic activity of XAMI on octopamine-sensitive adenylate cyclase, XAMI was more potent than p-octopamine by spinal or supraspinal administration in the abdominal constriction test (E50 = 0.013 micrograms i.t., 1.45 micrograms i.c.v.) and in the 48 degrees C hot-plate test (ED50 = 0.06 micrograms i.t., 0.4 micrograms i.c.v.), but was inactive in the tail-flick test (up to 4.0 micrograms i.c.v. or i.t.). Unlike p-octopamine, both XAMI and DCDM were active by peripheral routes of administration. DCDM was orally active in the mouse acetylcholine-induced abdominal constriction test (ED50 = 9.98 mg/kg p.o.) and was active via the s.c. route in this test (ED50 = 2.36 mg/kg), the 48 degrees C hot-plate test (ED50 = 5.40 mg/kg) and the tail-flick test (ED50 between 15 and 30 mg/kg). It appeared to be a full agonist against these endpoints. XAMI produced dose-related antinociception in the abdominal constriction test (ED50 = 0.10 mg/kg s.c.) and in the 48 degrees C hot-plate test (ED50 = 3.71 mg/kg p.o. and 0.46 mg/kg s.c.), where the antinociceptive response persisted for at least 60 min following subcutaneous or oral administration. Both compounds were less potent via peripheral routes than clonidine (as reference) in these tests. Mechanistically, XAMI-induced antinociception was antagonized by yohimbine and idazoxan, but not the opiate antagonist naloxone.(ABSTRACT TRUNCATED AT 250 WORDS)

Receptors for 3H-octopamine in the adult firefly light organ.

3H-Octopamine binds reversibly and with high affinity to sites on adult firefly light organ membranes. The binding is characterized by multiple affinities. Scatchard analysis supported a two site binding model with a tentative Kd value of about 1 nM for the high affinity component. The more abundant lower affinity site had a Kd value of about 60 nM. Guanyl nucleotides (Gpp(NH)p and GTP) greatly reduced the apparent number of octopamine binding sites. Competition studies with known octopaminergic agonists including the formamidine pesticides chlordimeform (CDM) and N-demethyl chlordimeform (DCDM) showed the following rank order of potencies in displacing octopamine: DCDM greater than octopamine = synephrine greater than naphazoline greater than clonidine greater than CDM. It was also observed that phentolamine was much more active than propranolol in antagonizing OA-binding. These relative activities are similar to the abilities of the same compounds to alter adenylate cyclase activity in light organ homogenates. Together with the effect of GTP on binding, these results suggest that the binding sites are functional octopamine receptors of the light organ.

The bradycardic and mydriatic effects of chlordimeform and its demethylated analogs in the rat: antagonism by idazoxan but not by prazosin.

Pupillary and cardiac responses to i.v. injections of chlordimeform (CDM, 0.3-10 mg/kg), a formamidine insecticide, and its metabolites demethylchlordimeform (DCDM, 0.03-1 mg/kg) and didemethylchlordimeform (DDCDM, 0.1-3 mg/kg) were studied in rats anesthetized with pentobarbital. Both CDM and DCDM induced a dose-dependent mydriasis and bradycardia and DCDM was 10 times more potent than CDM in causing these effects. In contrast, DDCDM did not induce a mydriasis or bradycardia. The alpha 2-adrenoreceptor antagonist, idazoxan (0.2 mg/kg, i.v.) abolished or reduced CDM- and DCDM-induced mydriasis and bradycardia, whereas the alpha 1-adrenoreceptor antagonist, prazosin (1.5 mg/kg, i.v.) did not change these effects of CDM and DCDM. SKF 525-A (50 mg/kg, i.p.), an inhibitor of enzymatic demethylation, administered 10 min before the first dose of CDM, failed to reduce the effects of CDM. The results suggested: 1) the mydriatic and bradycardic effects of CDM and DCDM are mediated by alpha 2-adrenoreceptors, 2) the monodemethylation of CDM increases its alpha 2-adrenoreceptor agonistic activities, but the didemethylation of CDM abolishes these activities, and 3) CDM can exert alpha 2-adrenoreceptor agonistic activities without undergoing a demethylation process.

Mode of action of bullatacin: a potent antitumor and pesticidal annonaceous acetogenin.

Bullatacin, a compound isolated from plants of the Annonaceae, and its analogues show in vivo potential as antitumor agents based on their efficacy in normal mice bearing L1210 murine leukemia and athymic mice bearing A2780 conventional ovarian cancer xenografts. These compounds also have interesting potential as insecticides and inhibit respiration in insect-derived Sf9 cells with high potency. Their toxicity in both cases probably arises from their strong inhibition of mitochondrial electron transport with a specific action at complex I.

Mode of action of formamidine pesticides: an evaluation of monoamine oxidase as the target.

The ability of formamidine pesticide, chlordimeform (N'-(4-chloro-o-toyl)-N,N-dimethylformamidine) (CDM), and several of its major metabolites to inhibit monoamine oxidase (MAO) in mouse tissues in vitro and in vivo was examined, and related to the hypothesis that inhibition of MAO is responsible for the lethal effects of CDM. CDM was a readily reversible inhibitor of MAO of medium potency as were most of its metabolites. However, the hydrolysis product, N-formyl-4-chloro-o-toludine (CT) was a significantly more potent reversible inhibitor. A comparison of MAO from brain, liver, and intestine showed no marked variations in their sensitivity to these inhibitors. Greater inhibitory potency was found using Type A substrates (5-hydroxytryptamine) than Type B substrates (beta-phenylethylamine). The activity of MAO in vivo after pretreatment of mice with CDM or its metabolites was assessed in liver and intestine by measuring the amount of [14C] tryptamine which still survived 5 min after an intraperitoneal injection. Established inhibitors of MAO gave appropriate results with this method. CDM also increased tryptamine recoveries but only at does which caused mortality, and then to a lesser extent than MAO inhibitors such as tranylcypromine, pheniprazine, and harmaline at sub lethal doses. For this reason, and in view of the lack of correlation of toxicity to MAO-inhibitory potency among CDM and its metabolites, and because the symptoms of poisoning are inappropriate, it is concluded that MAO inhibition is not an important factor in the acute lethality of CDM.

Determination of structure-activity relationships of Annonaceous acetogenins by inhibition of oxygen uptake in rat liver mitochondria.

A new group of natural compounds, the Annonaceous acetogenins, have recently been determined to inhibit ATP production at a similar site of action and higher levels of potency as rotenone, i.e., at NADH-ubiquinone oxido-reductase, complex I of the mitochondrial electron-transport chain. The acetogenins had earlier been determined to be pesticidal, antimalarial, antimicrobial, anti-parasitic, cytotoxic, and in vivo active as potentially new antitumor agents. In order to determine structural activity relationships (SARs) among these compounds, at the subcellular level, several available acetogenins have been tested. Data obtained, from the inhibition of oxygen consumption by rat liver mitochondria, demonstrated that all of the twenty acetogenins tested are active with IC50 values in the range of 15-800 nM/mg protein. The IC50 value of rotenone was 17 nM/mg protein. The bis-adjacent THF ring acetogenins and the bis-nonadjacent THF ring compounds are about ten times more active than the mono-THF ring acetogenins. Overall, 30-OH and 31-OH-bullatacinone were the most active and were slightly more active than rotenone. The least active were the 4-deoxy bis-adjacent THF ring compounds followed by the mono-THF ring group. There was some variation between the groups, e.g., within the bis-adjacent and mono-THF ring groups, the alpha, beta-unsaturated-gamma-lactones were less active than the keto-lactones, but this observation was reversed for one of the pairs of bis-nonadjacent THF ring acetogenins. Additional hydroxylations, to a maximum of three, seemed to increase activity within all of the groups. Before final decisions on SARs can be made, additional comparisons of the results of this subcellular assay (as an in vitro assay) with the results of in vivo assays should be made. Also, future investigations into the exact site of action within complex I and other possible sites of action (such as the NADH oxidase of plasma membranes) need to be conducted for a more. complete understanding of the utility and potential of this new group of very potent compounds.

In vitro and in vivo effects of formamidines in locust (Locusta migratoria migratorioides).

In vivo and in vitro experiments were used to study the effects of formamidines in the locust, Locusta migratoria migratorioides. In vivo the lethal and the antifeeding effects, in vitro the inhibition of the binding of a selective 3H-ligand to the receptors of octopamine, tyramine, dopamine, serotonin and gamma-amino butiric acid were studied. We have demonstrated that demethylchlordimeform is specific agonist to octopamine receptor, having high affinity to octopamine receptor, a moderate affinitiy to tyramine receptor and a low affinity to dopamine, serotonin and to gamma-amino butiric acid receptors. The demethylated chlordimeform analogoues, demethylchlordimeform and didemethylchlordimeform have higher affinity to the octopamine receptor than the parent compound. The formamidines had a toxic and an antifeeding effects when injected into the locust. The half lethal doses (LD50) and the feeding inhibition were correlated with the affinity of the compounds (Ki). The ring substitutions of the mulecule have alterated the both affinity and in vivo effect of the compounds. The most effective ring substitution pattern is 2,4-disubstitution with a combination of methyl groups or halogens. Our results suggest that the lethal effect of formamidines is mediated through the octopamine receptor.

Comparative metabolism and selectivity of organophosphate and carbamate insecticides.

The comparative metabolism and toxicity of organophosphorus and carbamate insecticides are reviewed with the purpose of assessing our present ability to design new toxicants with improved selectivity. The occurrence of quantitative and qualitative differences in metabolism in vertebrates and insects is considered and an assessment is made of the role of metabolic activation and degradation in the complex interactions governing toxicity.

Inhibition of insect acetylcholinesterase by the potato glycoalkaloid alpha-chaconine.

Homogenates from several insect species were assayed for inhibition of acetylcholinesterase by the potato glycoalkaloid alpha-chaconine. Colorado potato beetle acetylcholinesterase was up to 150-fold less sensitive than other species tested. Acetylcholinesterase from an insecticide-resistant strain of Colorado potato beetles was more sensitive to inhibition than the susceptible strain. Most insect species tested had inhibitory concentrations causing a 50% reduction in activity in the 5 to 40 microM range. Sensitive insect acetylcholinesterases were similar to mammalian cholinesterases in their response to alpha-chaconine. The results indicate that pesticides and host plant resistance factors may interact at the same target. Changes in the target due to selection pressure from either pesticides or host plant resistance factors could affect the efficacy of both control strategies.

Octopamine uptake and metabolism in the insect nervous system.

Several insect tissues were examined for their ability to take up octopamine in the presence and absence of sodium ions. The cockroach Malpighian tubules, ovary, and ventral nerve cord showed the highest level of sodium-dependent uptake. The adult firefly lantern exhibited substantial sodium-independent uptake. Some of these tissues were also examined for their ability to metabolize octopamine by N-acetylation. Measurable N-acetyltransferase activity was present in the cockroach ventral nerve cord, tobacco hornworm CNS, and firefly light organ. N-Acetylation is proposed to be the major metabolic pathway for octopamine in the cockroach (Periplaneta americana) nervous system. Several classes of compounds, including octopamine receptor agonists, tricyclic antidepressants, amphetamines, chloroethylbenzylamines, and some experimental insecticides, were tested for their ability to inhibit octopamine uptake and metabolism. The sodium-insensitive component of uptake was not inhibited by most compounds tested, but the sodium-sensitive component was strongly inhibited by xylamine, N-ethyl-N-chloroethyl-o-bromobenzylamine, and their aziridinium ions (60-100%). These compounds also effectively inhibited N-acetyl-transferase (IC50 values at or below 1 microM). Other good inhibitors of N-acetyltransferase included desipramine, synephrine, and an experimental insecticide, CGA 132427. Formamidine pesticides had limited effect on both processes, and neither action seems likely to be involved in their octopaminergic actions in vivo. Cocaine was unique in stimulating N-acetyltransferase activity. When inhibition of sodium-sensitive uptake is compared with inhibition of N-acetyltransferase in the cockroach ventral nerve cord, two groups of inhibitors are discernible. Type 1 compounds inhibit uptake without an effect on N-acetyltransferase, whereas type 2 compounds inhibit both processes. These results suggest a functional linkage between the uptake and acetylation of octopamine.